Electronic transport through single polyalanine molecules

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Diana Slawig
  • Thi Ngoc Ha Nguyen
  • Shira Yochelis
  • Yossi Paltiel
  • Christoph Tegenkamp

Organisationseinheiten

Externe Organisationen

  • Technische Universität Chemnitz
  • Hebrew University of Jerusalem (HUJI)
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Details

OriginalspracheEnglisch
Aufsatznummer115425
FachzeitschriftPhysical Review B
Jahrgang102
Ausgabenummer11
PublikationsstatusVeröffentlicht - 9 Sept. 2020

Abstract

Helical molecules have recently attracted interest due to their capability for robust spin polarization of transmitted electrons. By means of mechanically controlled break Au junctions, we analyze the transport properties of single lysine-doped and cysteine-terminated polyalanine (PA) molecules of various lengths (2.4-5.4 nm). The conductance varies exponentially with the (effective) length of the molecules and does not depend on the temperature (90-300 K), thus electron tunneling is the dominant transport mechanism. The decay constant for the PA molecule is found to be 3.5nm-1, significantly smaller compared to those of other organic molecules, emphasizing the high conductivity along the helical polypeptides and reflecting a low tunneling barrier, which decreases further for fields exceeding 5×105V/cm. The conductance histograms of all PA molecules investigated reveal characteristic satellite peaks, which correlate with the apparent molecule length in multiples of characteristic peptide sequences. We attribute this effect to a racheting of interdigitated molecules adsorbed on each side of the electrodes during the opening/closing cycles.

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Electronic transport through single polyalanine molecules. / Slawig, Diana; Nguyen, Thi Ngoc Ha; Yochelis, Shira et al.
in: Physical Review B, Jahrgang 102, Nr. 11, 115425, 09.09.2020.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Slawig, D, Nguyen, TNH, Yochelis, S, Paltiel, Y & Tegenkamp, C 2020, 'Electronic transport through single polyalanine molecules', Physical Review B, Jg. 102, Nr. 11, 115425. https://doi.org/10.1103/PhysRevB.102.115425
Slawig, D., Nguyen, T. N. H., Yochelis, S., Paltiel, Y., & Tegenkamp, C. (2020). Electronic transport through single polyalanine molecules. Physical Review B, 102(11), Artikel 115425. https://doi.org/10.1103/PhysRevB.102.115425
Slawig D, Nguyen TNH, Yochelis S, Paltiel Y, Tegenkamp C. Electronic transport through single polyalanine molecules. Physical Review B. 2020 Sep 9;102(11):115425. doi: 10.1103/PhysRevB.102.115425
Slawig, Diana ; Nguyen, Thi Ngoc Ha ; Yochelis, Shira et al. / Electronic transport through single polyalanine molecules. in: Physical Review B. 2020 ; Jahrgang 102, Nr. 11.
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title = "Electronic transport through single polyalanine molecules",
abstract = "Helical molecules have recently attracted interest due to their capability for robust spin polarization of transmitted electrons. By means of mechanically controlled break Au junctions, we analyze the transport properties of single lysine-doped and cysteine-terminated polyalanine (PA) molecules of various lengths (2.4-5.4 nm). The conductance varies exponentially with the (effective) length of the molecules and does not depend on the temperature (90-300 K), thus electron tunneling is the dominant transport mechanism. The decay constant for the PA molecule is found to be 3.5nm-1, significantly smaller compared to those of other organic molecules, emphasizing the high conductivity along the helical polypeptides and reflecting a low tunneling barrier, which decreases further for fields exceeding 5×105V/cm. The conductance histograms of all PA molecules investigated reveal characteristic satellite peaks, which correlate with the apparent molecule length in multiples of characteristic peptide sequences. We attribute this effect to a racheting of interdigitated molecules adsorbed on each side of the electrodes during the opening/closing cycles.",
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AU - Slawig, Diana

AU - Nguyen, Thi Ngoc Ha

AU - Yochelis, Shira

AU - Paltiel, Yossi

AU - Tegenkamp, Christoph

N1 - Funding Information: We gratefully acknowledge the financial support from the VW Foundation (Grant No. VWZN3161).

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